44
qNXY4RSITY Otwil MISUR OLLA
ON. -SH-
747
ISEP
'1 PENETRATIO~NTIN NA GATEC HPECHARGINR
INORMVAIOSMETALSE
Sp-gtod Va.,, 2215
RMERC-TR-70-W-iROCK MECHANICS & EXPLOSIVES RESEARCH CENTER
UNIVERSITY OF MISSOURI - ROLLA
Details of illustrations int_ document may be betterI " ,tudied on micr~ofiche
PENETRATION IN GRANITE BY SHAPED CHARGE LINERS
1 1 OF VARIOUS METALS
by
R.R. Rollins, Assoc. Prof. of Min. Eng.,& Sr. Invest. in RMERC;
G.B. Clark, Pof. of Min. Eng.,& Director, RMERC;
H.N. Kalia, Grad. Res. Asst., RMERC
I'I Approved for public release; distribution unlimited
IFinal Report for
DuPont De Nemours Co., Inc.1 Wilmington, Delaware
and
I Corps .f EngineersMissouri River DivisionI |Omaha, Nebraska
Contract No. DACA-45-69-C-0087
1 April 1971
I I. INTRODUCTION
A. General
The term "shaped charges" is generally applied to high explosive cy-lindrical charges with lined or unlined cavities formed at the end opposite
I to the point of initiation. The unlined cavity effect is known as the Mun-
roe effect in the United States and the United Kingdom (1), the Neumann ef-
fect in Germany, and the cumulation effect in Russia (2). There is no evi-
dence that Munroe or Neumann discovered the lined-cavity effect, which is
3 |a phenomenon quite different from the unlined-cavity effect. Baum (2) has
* credited Sukhreski with the systematic investigation of the cumulation ef-
fect, Eichelberger (3) credits R.W. Wood with the recognition in 1936 of
I the usefulness of metallic liners in the hollowed charges to produce frag-
ments of extremely high velocity. Fundamental and developmental studies
Ias well as the design of shaped charge weapons were simultaneously under-
taken by DuPont's Eastern Laboratories, and by Kistiakowsky, Taylor, Mac-
Dougal, Jacobs, and others in.1941tThis-study-was-under-taken,.to determine the penetrability of shaped
: 3charge jets into granite utilizing metallic liners and composition C-4 asthe high explosive. While shaped charges have found extensive use in mili-
tary applications, industrial uses are limited to oil well casing perfora-
tions, furnace tapping, and linear metal cutting charges.(IW
Lined cavity charges were investigated by Clark (4), Austin (5), and
I Huttl (6), to evaluate their effect in breaking concrete, rhyolite, and
limestone boulders. From the literature it appears that no systematic in-
I vestigation has been made to evaluate shaped charges for drilling and blast-
ing rock. The capability of relatively inexpensive shaped charges to form
I. high velocity jets makes them of interest for possible application in this~operation.
B. Nature of the Investigation. The primary objective of this study was
I to evaluate the penetrating capability into rocks of shaped charges fabri-
cated from selected liner metals. The following parameters were investigated:
9 11) property effects of six different liner metals, 2) change in the physical
i
A
properties of liners by annealing, 3) behavior of rock under jet impact,
and 4) jet characteristics, formation, and penetation theory.
A large amount of information is available on the penetration of
3 metallic targets by metallic jets. The first order penetration law was
developed independently by Pack, Mott, and Hill (7), Pugh (1), and Pack and
Evans (P, 9) applying Bernoulli's theorem. The total penetration is given
by:
P = L (pj/pt) (I)*
Equation (1) holds only for ideal jets and for targets with zero yieldi iI strength as compared to the pressure of the jet. Thus, one expects varia-
tion from this law for nine ideal materials. it is observed that the re-
sistance to penetration in rock is due not only to the density of the jet
and its length ond the density of the rock, but to other factors as well,
e.g., the joints, bedding planes, porosity, and the anisotropic nature of
I the target.
III. THEORY OF JET FORMATION AND PENETRATION
The classical two-dimensional theory of jet formation (8, 10) has been
modified (3) to account for the jet tip velocity gradient. The modified two-
dimensional theory visualizes the liner collapsing upon itself due to the pres-
sure of the detonation products. As the pressure is applied progressively to
the liner, it collapses upon the axis at an angle a (Figure 1). This collapse
angle is greater than the apex angle of the cone.
The two-dimensional theory and other similar theories neglect the accel-
eration of the coordinate of the stagnation point and the thickening of the
liner. In order to account for these parameters one requires the solution
of a three-dimensional time dependent configuration.
j A. Theory of Cone Collapse and Jet Formation. The analytical technique
used for collapsing cylindrical shells (11) may be applied to coliapsing
SI * List of symbols -Appendix A
2
I
conical liners. According to this theory, wi,ep ?n undisturbed cylindrical
I shell contracts the velocity of the outher surface would tend to diminish and
the inner velocity should increase (Figure 1). As an initial approximation,
I it is assumed that the liner material is incompressible and that the wall
moves inward normal to the original surface of the cone.
For a cone of half apex angle a (Figure 2) the kinetic energy of a thin
element of unit thickness can be obtained by considering the section to col-
lapse along the slant height of the cone AB. The kinetic energy of this ele-
I' ment is
T = prcosa(S3S3)2 In S2/S 3 (2)
or the time of collapse is given by
; I3i (S3 + dtc = (piAl cosa/T)2 1/2 S3!n dS3 (3)
3S3TrCosa
Equation (3) may be numerically integrated for successive values of S3i
5, and the time of collapse determined for a constant collapse velocity. For a
constant jet radius the movement of the stagnation point is constant (Fig. 3).
SI, This partially explains why the two-dimensional theory offers such a good ap-
proximation for a three-dimensional process. Modifications similar to those
U employed by Eichelberger (12) and Jackson (13) will yield more accurate evalua-
tion of jet formation and of the physical processes involved.
B. Theory of Jet Penetration. The basic theory of penetration by high-speed
metallic jets was developed using Bernoulli's theorem (Equation 1). Various
authors have modified this equation i-iit: empirical constants to explain pene-tration of various types of metallic targets; however, it does rot take into
account tne jet velocity and target strength. Dipersio (14) has modified the
I equations developed by Allison and Vitali (15), and the concept of his theory
(14) treats three cases: (a) a continuous jet, (b) a partially continuous jet,
I and (c) a completely discontinuous jet. The total penetration for these three
conditions is given by
: z[VI/( + Y)Unhin -l (4)
1 3
I
Stagnation Point
- - -- , --- ,o Detonation, - Front
' ' Li ner
I Jet
i Figure 1. cone Collapse and Jet Formation
K:I
j ~r B
IFigure 2. Cone Collapse Dimensions
4
SPT (1 + ) (VI3tl)l/(l+ )Zo0 / (1+Y)T (5)
1 (1+ y)Um i n tl(Vjt I 1 0Y)Z Y/O+Y)
0 vt l tmi (Vgtl + yZo) (6)
Y
5, ..~The basic assumptions in the development of equations (4), (5), and (6) arethat the target and jet are incompressible, the jet originates at a distance
Zo from the target, the jet breaks up axially into individual particles simul-
1 taneously throughout its entire length, and all particles above a criticalvelocity for a particular target contwibute to penetration.
FFor a given charge and target thE penetration increases linearly WithZ for a continucus jet (equation 4). The penetration increases with jet tipvelocity and with a decrease in umin, the minimum penetration velocity, both
of which can be determined experimentally. The jet tip velocity is a function
of liner and explosive properties.Maximum penetration is obtained at the upper limit of application of
equation (6), which defines the penetration for a partially continuous jet.
I The maximum penetraLion is given by
Pmax . [V umin ( ° Zo)] (7)
Maximum penetration is obtained lor high jet tip velocity and optimum jetbreakup time, t I . This equation offers an explanation of the reason that
I high velocity explosives and high density cohesive jets produce a maximumtarget penetration.
I i6
I III. EXPERIMENTAL DESIGN
, A. Design of Shaped Charges. A concise suimary of shaped charge design is
given by Klamer (16). For this investigation the following design parameters
were considered:
S 1' (1) liner material, (2) apex angle, (3) liner thickness, (4) charge di-
mensions, (5) type of explosive, and (6) target material.
1' 1. Liner material. Zernow (17) tested several metals For shaped charge
liners and arrived at the conclusion that copper, nickel, iluminum, and silver
I (all face centered cubic) behave in a similar manner with few noticeable dif-
ferences between them. They respond 'in a ductile fashion in the dynamic Br:lg-
ri man region, and stretch in a taffy-like manner in the jet flight phase. Copper
'is the most effective liner material for metal targets because of its ductili-
I ty, cost and density.
Iron (body centered cubic) and all 1020 mild steels showed high ductility
ri in the dynamic Bridgman region but fractured in relatively large fragments
shortly after leaving the high pressure region. The hexagonal metals tested
by Zernow (17) show distinct characteristics. In the flight phase the jets
I from these metals break up into fine fragments. Magnesium shows a ductile
nature in the dynamic Bridgman region while cobalt exhibits an anomalous be-
Il havior.
Metals under higher pressures (21,000-31,500 kg/cm2 ) show a different
3i degree of elongation than they do under ambient pressures. The amount of
energy imparted to plastic flow and fracturing changes as pressure is in-
creased (18), hence the mode of liner failure will change with the applied
Ipressure. Metals having low melting points, cadmium (hexagonal), zinc(hexagonal), lead (face centered), and tin (tetragonal), all behave in a
I unique manner despite the diversity in their crystal structure. It appears
that for thp,;e having melting points - 6250C the crystal structure corre-
lates with the observed behavior of the jet, whereas in low melting point
metals, 4600C - T < 625'C, the low melting point itself appears to be best
correlated with the behavior of the jet.The metals selected for this investigation are presented in Table 1
with their physical properties.
7
I
rr.r-r- C')
'0 C:0 1.0 0r_4- .) I I
Cl(Y (1) 04 0~ * CO
L0~
A 4) U)
fC'flL CD COj CQ mO 0O
Mi WWE N N k l C94--
(A 0 42 - C)
,- r- .0 04)
(0~ t.rc4 a- In 4- Wal 04-) -. )C. C) - I COj 0) GA S- C .. a '(1 4-C) oo r" N n LAz P
'a (0- X . - r-5- 0 r- t - I N CO CO a- Ya) ZLLJA r1 4-- V- I LO
. . a-CO0-I4- 0- to0
4- a - wS-UCJa LU 0 co '. a-
0)~~~V LO LLDO 000~ '0 O ~ ~ .- .
M . 4-) 0 .S.- CL 0) C.. aoo '.0
0.. (m LA) N-) 0-) N-X' '40005. a- a- Nl N a- Lo 0) a'.
r -ar- G) (0(0 LLW4-) 0 4-) LO LO a-Ln
Q) LLO~NCY)
>)- 0) : r
(U CWf CD C LA Cx) LO ') 0ZipU tCL ) u C. ) NOCj-Z '69 .E S.-%X cO; CCO NO (0 CO C
0) 4- 0 0
r-~~~ ~ ~ ~ a- -, 0) 0.0 1 .0 0 l
fI ra-0) 04-) 0
rIOm xcc> )LM r- 3 r 3: 8
2. Apex angle. Conical liners were used in this study because they
are easy to machine and have proven to be one of the most effective geometries.
Brimmer (19) has shown that for metallic targets the optimum cone angle for
maximum penetration is approximately 600, whi ;4 the cone angle employed
*' in this study.
3. Liner thickness. The liners were designed with optimum thickness
I(th optimum) which was obtained by using the relationship suggested by
Winn (20):
0 th Optimum Copper)(Density of Copper)1th Optimum = (Density of Metal) (8)
The optimum thickness of the copper liner was taken as 0.105 cm for 60°
|c cones of 5 cm diameter.
The average weights and thickness of the liners were:
Metal Weight (gm) Liner Thickness (cm)
Aluminum 2011 (T-3) 32.5 ± 0.25 0.3500 ± 0.002
Aluminum 7075 (T-6) 32.0 ± 0.25 0.340 ± 0.002
I Yellow Brass 36.1 ± 0.25 0.1150 ± 0.002
Maraging Steel 34.7 ± 0.25 0.1161 ± 0,002
Monel 34.2 + 0.25 0.1065 ± 0.002
Copper (42 degree) 47.9 ± 1.00 0.1050 ± 0.002
4. Charge Dimensions. The charge length must be sufficient to provide
a fully developed detonation front before it makes contact with the apex of
I the liner. Baum (2) points out that the minimum height of the charge for
which its active portion attains its limiting value for a cylindrical charge
is equal to Hlim CR + h. Thus, Hlim for conical liners is approximately
equal to 2 cone diameters. Framing camera photographs show that the detona-
tion front for C-4 is fully developed when it contacts the cone for a length
of 2 cone diameters. Based on these observations and the literature review a
standard charge length of 2 cone diameters was used, which in the present in-
vestigation equalled 10 cm. The charge to cone diameter ratio was 1.04.5. Type of Explosive. The characteristics of explosives commonly employed
jin shaped charge studies are presented in Table 2. The most desirable proper-
ties are high detonation pressure and velocity. Composition C-4 (Table 3)
j possesses these characteristic3 and is easy to load by hand. The explosive
I
I0
CIO*r 0 (AUo, i -o " i a ~ 5 c (JO
a. ) *c.D n-t : V uaS.. .i rC (fU W .r-' O C ."-(A > a) Ln " (D0 4 - ".,.,
4( 4- )U -- -.-
(MI 0 0 4- (a ' = L 4- 0n s- X- C0
- ' ' 4 U o)0 ( -ug:a o 4J (A .,.- 4-) 4- -
4I)
= 0,, 3 * -a > (D--4- 0 .- 0 )0 . 0-
0e-lo v o- aJ.E - 0nS- - -(
{ .I.X Ln ,S- n Q) 4-}-0: >, a) S.- ' M ( ,0 U 0-
(a"M o 4- a) OL 0 E .,..0 U=I:0 M 4- C LO 4- 00 4- CO 0
(A-CD 4- C (A o ) I %a) 4 ,-4
#A c~ o )0 =O -0 *u (ne- ) 0
oI 0," ) 0 W,- 04 -U S- ,E 4-) u 4 o - mo or- m 0,D - 0 (a- 0"a 0 S.- r" ;: I:-
W 4- 0,r- LO a) CL( E 4-) - W CC,-UI. MJ0 0 =- X V)w, = V) =~ .. Z-;.. "0
-- CD 4- a) Mh a) O M- D¢)-C 44-.3 LO3 0 - ..( o m -. 0 1 M -
I-
1 0
4--
.r,' a) > ) > D ) w-. a)
" ) I- (a •r (a •
,i o o CO>4. 8 4) 41o fO 4-- iv V 4-) 4)4-)_
I *
I 10
a) J 0 E - 4J
E r-
m~ 00 CD
C- r- *~ I
EU,-fl 0 0) 0f) LO.) r-V In0 rC,-
0)0) 0
0
0.5. 4 J V ) LO CDJ C) C)*-*r- W N.D.n C O mr
00 00D a4Jr J -- r-- :~ 43 30
too
0.f (DJN J
0 LL. (1
-0MV 0 TLfl 0 C
0)c a) ()O 0 = 'a4.) (a *.O CL, a) ) t a
t o C 4 >C 4-J D 0
a) > CYr) -a r_
S- t
(1) >) <Ja
.9-) >1 0Lf
0.. S. r -a
S- a) 4-)00~ a (aI I J r-o S- 0 -) aCC > t
a)J 4J a-) E 00 I- -
"Lot V)--CL--44-- S-' - -4
r_ . )() J0 Ct
Q)) a).. ' '0 4- Q) M00 Q
4Ja >'. 0). +-) 0f 00oa)t
gUr-') ) Q0 U0 Co A 0 LA- 00
00X M. 4-0 0 0 0 .cu (0j1~ u- (L) CO V) '.1 U - C 01
a))
4-U)(oa 0)C a
Qci . 0 > .0
co IV as $-I to4- 0 4-) 4- 4-3 *( ) 4-(J aC r-r-02 I
0.. f~.U -)r01 ~ )-)-
CLE01 L- OL. .'.)(..I)..0. V0E -
LLI 4-)1
-o
aa >i~~S I 1 )J
S- a) 0 0 0 0 r
VD V)-r0 W CW r ' (
0)4 Q.r- O3S 4-) S.-
4-) .(0 4,- CU WO 0P- C 4o-) -)
.0 >) 4- 0h (A e 0- (U,-a) . - Q) 0 w 0 0-
j - J C
u0(a 4-) - 0 M-! (0.0 530r-d> D CL - . C.r---
I -n . e',0-
-'%d U.,1 4- 5- 3-,Q(o,1 W/0 W, 4-' 01 CUU
a) U..- - S- u S- tw ( a a - WD o >, 0 W
" r- E >"4-M - " 000D S- -- W~-r B: 4-)
CMoa) a) 0- Pu c
I IIV ..U.,010 S .r'- I a --
(v 0t4- 4-' >~ 4- ocoS-
-0 X o >MQ) (4J o
() .u 0.,
4-) U, z_ aV --
(U u
4-)) 0.
,0 I -
(AM 4 L V- (A) 4-4J W) >
M 0 a--
SD .. - )
a) a)C -x
0 00 Li 4)
O . _ >
I 00. .-
'UC, S- w- ) a- *e-
.(- 0
4- C ->
C C.D OCS.
•0 -r,- a) "
Ci\-J.~ 4..f-~ 4-' ,W.. 0 4
F- d) >U0
CL- a)) r-I0
itox U 5 4>SO 4-- U,) -
V) ') S- M0 Uq ~ .- 0r-I cl.. C\. S- *c
-42
!(i>
(A I
0 -
2'I
I Table 3
Properties of Composition C-4I, Heat
Empirical of FormationComposition C-4 Percentage Formula Kcal/MoleI RDX 91.0 C 3H 6N606 -18.3
Polyisobutylene 2.1 C4He -l9.7***
Motor Oi! (SAE 10) 1.6 CH2 - 4.9
I Di-(2-ethylhexyl) 5.3 C26H500 -306.9***3, Sebacate
I Empirical formula for C-4 C1 .8oH 3.ooN 2.46O2.5o
Heat of formation for C-4 -126.1 Kcal/mole
I Heat of reaction for C-4* 983 cal/g
For this data, a density of 1.59 g/cm3 , and the B.K.W. equationof state, the following parameters were computed: #
Density 1.59 g/cm 3
Detonation velocity 8,578 m/sec
I Particle velocity 2,320 m/sec
I Sound velocity 6,258 m/sec
Detonation pressure 312,333 atm
Detonation temperature 3,3740 k
Total gas 34.667 moles/kg of explosives
j Total solid (carbon) 12.176 moles/kg of explosive
Experimental value from oxygen bomb calorimeter measurements, personal
communication from personnel at Picatinny Arsenal.
** Operator's Manual for RUBY, UCRL 6815 or TID 4500.
I. *** Personal communication from Dr. D.S. Wulfman, UMR.
I
was loaded at a density of 1.6 gm/cc at which it has a theoretical velocity
I of 8611 m/sec and a pressure of 327,069 kg/cm 2. A mechanical device which
applied a controlled pressure was used to ensure uniform loading of the ex-
plosive, and a No. 8 blasting cap was adequate for detonation.
6. Target Material (Table 4). Initial tests were performed on cast
concrete blocks (Table 5) and rhyolite (Table 6). However, these materials
K were too weak and brittle, and it was not possible to obtain hole dimensions.
Missouri red granite was used as the target material for most of the data ob-
S tained in this investigation.
Table 4.14 Physical Properties of Target Materials
K Density Impact Compressive Compression ApparentRock Type Hardness Strength Wave Velocity Porosity
g/cc g/cm 2/l04 cm/sec x 10'
Concrete 2.069 31* 84.0 4,45* 18369Rhyolite 2.620 -- 337.0 ---- 0.16Missouri 2.60 53* 119.0 4.52* 0.4Red Granite
*Reference (21)ITable 5
Penetration in Concrete by 600 Liners
Charge Liner Thickness Standoff Penetrationj No. cm cm cm
35 S 0.1161 20.0 22.536 S 0.1161 15.0 38.537 S 0.1161 5.0 31.538 S 0.1161 10.0 17.549 A16 0.3480 15.0 39.650 A16 0.3480 20.0 22.853 A16 0.3480 15.0 35.5
S Maraging Steel (Vascomax 250)A16 Aluminum 7075 (T-6)
'II 14
I
I Table 6
I Penetration in Rhyolite by 600 Liners
Charge Liner Thickness Standoff PenetrationI No. cm cm cm
42 B 0.115 5.0 10.043 B 0.115 10.0 20.044 B 0.115 17.5 15.045 B 0.115 29.0 22.552 A16 0.348 20.0 10.054 A16 0.348 15.0 10.0
B Yellow BrassA16 Aluminum 7075 (T-6)
FTable 7
Optimum Standoff
F Aluminum 2011 (T-3) 20.0 cm or 4.0 CD
I Aluminum 7075 (T-6) 22.5 cm or 4.5 CD
Yellow Brass 15.0 cm or 3.0 CD
I Monel 17.5 cm or 3.5 CD
Maraging Steel 10.0 cm or 2.0 CD
Copper (42 degree) 16.25 cm or 3.25 CD
II
III| 4
I
U IV. EXPERIMENTAL RESULTS
A. Penetration Studies. Penetration depths not including spallation were mea-
sured with a graduated metallic probe. Holes were assumed to be a right circu-
lar cone, and spalled thickness was measured as accurately as possible. The
1I hole was plotted to scale and the slant surface extended to the original rock
surface. The radius so obtained was taken as the effective value at the surface.
An expendable template was designed to centrally locate the detonator and pro-
duce a symmetrical detonation front (Figure 4). Cha-ges were fired at variable
standoff to obtain the optimum value (Table 7). Optimum standoff was employed
in the experiments for measurement of the rate of penetration into granite by
jets from liners having 42, 55, and 75 degree apex angles (Table 8).
Penetration in Granite
Aluminum 2011 (T-3". Jets showed considerable variation in penetration, which
is attributable to nonl.hmogeneities in the rock and other experimental variables.
Liners with 42, 55, and 75 degree apex angles gave less penetration than those
with 60 degree apex angle. One liner was annealed for 20 hours at 413 degrees C,
but this resulted in less penetration. Maximum penetration was obtained at a
SI! standoff of 20.0 cm (4.0 cone diameters). (Figure 5, Table 9).
Aluminum 7075 (T-6). A gradual increase in penetration with standoff occurs
from 4.0 to 4.5 cone diameters. Penetration by jets from 42, 55, and 75 degree
-- liners when fired at optimum standoff for 60 degree liners showed less penetra-
tion. One liner was annealed at 413 degrees C fr, ir PfI ,rs, was fired at the
optimum standoff, and showed a slight increase in penetration. (Figure 6, Table 10).
Yellow Brass. Yellow brass gave greater penetration than al; other liners
tested. Liners having 42, 55, and 75 degree apex angles when fired at the best
standoff for the 60 degree liners gave less penetration than the 60 degree liners.
One of the 60 degree liners was annealed for two hours at 413 degrees C, The an-
nealed liner gave less penetration than the nonannealed liners. Maximum penetra-
Ition was obtained at a standoff of 15.0 cm.Three shots were fired in rhyolite and about 20.0 cm of penetration was ob-
served at 10.0 cm standoff. The reliability of the penetration data obtained
is questionable due to extensive fracturing of the target, because of the
brittle nature of the rhyolite and microfractures prcsent from the quarry blast-
I ing. (Figure 7, Table 11).
116
I Table 8
Penetration in Granite - 600 Liners at Optimum Standoff
Charge Apex Liner Stand- Penetration Hole HoleNo. Angle Thickness off Radius Volume
I deg cm cm cm cm cc
- 155 T3 42 0.2750 20.0 10.1 - +11 T3 55 0.2750 20.0 9.3 3.5 1 19 .3c57 T3 60 0.3500 20.0 15.0 - +154 T3 75 0.3160 20.0 9.9 1.2 14.93
j 157 T6 42 0.2750 22.5 12.2 0.9 10.35- 22 T6 55 0.2750 22.5 11.1 0.5 5.70
G T6 60 0.3480 22.5 13.2 - -34 T6 75 0.3160 22.5 9.1 - -
I19 M 42 0.1000 17.5 12.7 1.3 11.321 M 55 0.1000 17.5 12.3 0.7 6.365 M 60 0.1065 17.5 17.0 1.8 15.632 M 75 0.1000 17.5 9.7 0.9 8.2
159 B 42 0.1000 15.0 11.5 1.3 11.3160 B 55 0.1000 15.0 15.3 0.8 6.3100 B 60 0.1150 15.0 17.4 1.7 26.225 B 75 0.1500 15.0 13.9 0.9 22.518 S 42 0.1000 10.0 11.8 0.7 6.0
- 16 S 55 0.1000 10.0 11.7 1.1 14.81. 40 S 60 0.1161 10.0 16.0 1.5 37.7
30 S 75 0.1500 10.0 8.0 0.7 4.1
+ = Crater (no hole radius could be measured)
T3 = Aluminum 2011 (T3)
T6 - Aluminum 7075 (T6)I M =Monel
B = Brass
S : Steel
C = Crater
G = From graph
1 17
r wLIc 0
(as) CO)J U
t __ _3__ __S___ __ _
'4- CD
0 "0)
1~ tul- ri%
0 0 0*woY
LO ) 0 ,-i
C) ~ C\!i
LA LO
:18
*
j Table 9
Penetration in Granite - 600 Aluminum 2011 (T-3) Liners
rCharge Standoff Penetratien E.R.* .V'.No. cm CD+ cm CD+ cm cc
I 56 15.0 3.0 10.3 2.06 -60 17.5 3.5 13.0 2.60 2.5 85.1++
62 18.0 3.8 12.8 2.56 -V 57 20.0 4.0 15.0 3.0 -
118 20.0 4.0 12.7 2.54 1.0 13.3115 21.0 4.2 9.5 1.90 -
I 61 22.5 4.5 13.0 2.60 *59 25.0 5.0 8.0 1.60 *++
119 25.0 5.0 10.2 2.16 2.5 66.8I 58 27.5 5.5 13.0 2.60 2.0 54.5
116 30.0 6.0 8.8 1.76 *120 35.0 7.0 9.2 1.84 2.0 38.5
A130 20.0 4.0 11.2 2.24 1.2 16.9
+ = Cone diameters
* E.R. = Effective hole radius
**H.V. = Hole volume
= Hole was shattered
[I ++ = Conical crater with smooth walls
A Annealed liner
1
19
I
Table 10
I Penetration in Granite - 600 Aluminum 7075 (T-6) Liners
Charge Standoff Penetration E.R.* H.V.**
cm CD+ cm CD. cm cc
54 15.0 3.0 10.0 1.40 1.4 29.3
89 17.5 3.5 11.2 2.24 0.9 8.555 20.0 4.0 1-2.5 2,5087 22.5 4.5 8.5 1.70 4.0 142.A++83 25.0 5.0 13.0 2.60 4.0 217.8++88 27.5 5.5 10.0 2.00 1.0 11.084 32.5 6.5 12.0 2.4090 35.0 7.0 9.8 1.96 2.0 41.0++
A131 22.5 4.5 13.7 2.74 0.8 9.2
+ CD = Cone diameters
* E,R.= Effective hole radius
I **H.V.= Hole volume
W** = Hole was shattered
I ++ = Conical crater with smooth walls
A = Annealed liner
Table 11
Penetration in Granite - 600 Yellow Brass Liners
Charge Standoff Penetration E.R.* H.V. *
No. cm CD+ cm CD+ cm cc
98 5.0 1.0 13.0 2.6 --3. 99 10.0 2.0 13.0 2.6 1.4 26.7
48 12.5 2.5 16.5 3,3 0.8 11.1100 15.0 3.0 17.4 3.5 1.7 52.7103 17.5 3.5 14.5 2.9 1.0 15.2101 20.0 4.0 10.8 1.2 0.7 5.5104 5.0 1.0 12.2 2.4 0.7 6.3
A129 15.0 3.0 14.6 2.9 0.8 8.6
+ = Cone diameters
* E.R.= Effective hole radius
**H.V.= Hole volume
*** = Hole was shattered
A = Annealed liner
2
Monel Liners, 60 degree. Penetration by jets from 42, 55, and 75 degree
liners was less than that for 60 degree liners. One cone was annealed at
I871 deg C for two hours, and gave less penetration than the nonannealed cones.
One low value of penetration is attributed to large quartz crystals in the
itarget. The curve is somewhat similar to yellow brass with less scatter thanfor brass. (Figure 8, Table 12).
I Maraging Steel Liners, 60 degree. The best penetration was obtained at
10.0 cm standoff. The 42, 55, and 75 degree liners gave less penetration
,i than 60 degree liners. Since the penetration trend was not promising andthis metal required greater machining time, only three tests were made,
(Figure 9, Table 13).
3 Copper Liners, 42 degree. Fifteen jets were fired into granite using
42 degree copper liners with flanges, and nominal scatter was observed in
Sthe penetration data. Flanges were removed from 5 cones, and no significant
effects were observed. For this metal, penetration in granite seems to be
less sensitive to standoff compared with most other metals. Some of the
scatter in data was probably due to the variations in liner mass (46.8-49.5 gm)
and imperfections in manufacture. (Figure 10, Table 14).
Summary. The general trend of curves for all the metals is similar
(Figure 11), i.e., an increase in penetration with increase in standoff inaccord with theory until a maximum is reached, followed by a decrease in pene-
tration. Aluminum requires a greater standoff than other metals. This may
II be due to the cohesiveness of aluminum which is body-center cubic. All jets
have a velocity gradient, with the highest velocity at the tip. Hence, the
I breakup time of aluminum may be greater which would permit the formation ofa longer cohesive jet. Except for aluminum all metals show maximum penetra-
Ition at about 2.5 to 3.5 cone diameters standoff, whereas optimum standoff
for aluminum is between 4.0 and 5.0 cone diameters. Except for aluminum 7075
(T-6) all the annealed liners gave less penetration than nonannealed liners.
jThe scatter in the penetration data was due to the anisotropic nature of thetarget, variables in liner properties, loading density and other factors.1
I| 23
(Mj) UOPEJI1.uad
CD- '-
C.)
P_Li 0) co
cu s)- 5-LOl Lf) 0
<Ci C~j 0
C
1 4-
I V) CD0 00 C.')
LOI
N r_ 0
C/) Cy.)
1 0 WC4- I
00
4-',
r_ a) 0
10 4)
0) 0)
M LL-
0 UO P-
C- LO LO CD
Ii 24
I Table 12
Penetration in Granite - 600 Monel Liners
Charge Standoff Penetration E.R.* H.V.**No. cm CD+ cm CD+ cm cc
63 5.0 1.0 12.0 2.464 12.5 2.5 13.5 2.7 1.5 31.867 15.0 3.0 13.0 2.6 1.0 13.665 17.5 3.5 17.0 3.4 1.8 57.766 20.0 4.0 9.0 1.8 4.0 150.8++68 20.0 4.0 15.5 3.169 25.0 5.0 14.1 2.8 1.0 14.8
A128 17.5 3.5 13.4 2.7 0.9 11.4
+ CD = Cone diameters
j * E.R. = Effective hole radius
•* H.V. = Hole volume
I * = Hole was shattered
++ = Smooth wall conical crater
A = Annealed liner
Table 13
I Penetration in Granite - 600 Maraging Steel
(Vascomax 250) Liners
I Charge Standoff Penetration E.R.* H.V.**No. cm CD+ cm CD+ cm ccI39 5.0 1.0 14.5 2.90 2.0 60.74++40 10.0 2.0 16.0 3.20 1.5 37.7
41 15.0 3.0 10.0 2.00 4.0 167.5++
+ CD = Cone diameters
* E.R. = Effective hole radius
•* H.V. = Hole volume
++ = Smooth wall conical crater
1 25
(ao) UO~q'4U~
m.' I - C
E (M
i~
C)
B 4- LA-
4- -)j0 05-In~~- CM * ~d
c2J
4-i
COC%
(WD -O~j9- c9ua
-. C\JL In 2 6
I
Table 14
Penetration in Granite - 420 Copper Liners
Carge Standoff Penetration E.R.* H.V.**No. cm CD+ cm CD + cm cc
106 5.0 1.0 14.5 2.90 1 . 18.4108 10.0 2.0 13.5 2.70 0.9 11.5
107 15.0 3.0 24.5 4.90 1.2 36.9110 20.0 4.0 11.0 2.20 0.6 4.2112 15.0 3.0 10.2 2.04
'1 109 25.0 5.0 12.5 2.50 0.8 8.4124 5.0 1.0 10.6 2.42 0.9 9.0
125 15.0 3.0 13.2 2.64 0.8 8.8126 17.5 3.5 10.0 2.00128 25.0 5.0 14.8 2.96 0.9 11.2
-145 5.0 1.0 10.0 2.00 1.0 10.5-146 10.0 2.0 13.6 2.72 1.0 14.2
-147 15.0 3.0 14.3 2.86 1.0 15.0-148 17.5 3.5 10.8 2.16 1.1 13.7-149 22.5 4.6 13.2 2.64 1.1 16.7A127 16.3 3.3 14.1 2.82 0.9 12.0
I + CD = Cone diameters
-V * E.R. = Effective hole diameter
* H.V. = Hole volume
- Copper liners without flange
A = Annealed liner
Ii 28
~~j u
4-ia uoL a); u0 ~ a)r. U
4- V) r-. (
S-s
a)(1 a)-
) E 0 ). ro CE :3 EL -S-=o0 M O5- W x
4n LO) C13 yfm 0
0O 4-)/cc
~430g
I 00os
(W) CD4d~~~
1 29
LI
j The granite blocks had small joints and the grain structure was non-
uniform. Early tests with concrete had shown that joints have an effect on
T the penetration. The abnormally large penetration observed with copper liner
(charge No. 107, penetration 24.5 cm) could have been due to microfractures
in the granite from previous testing in the block.Copper jets do not exhibit a superior ability for penetration in granite
as they do in steel (19). The order of effectiveness for penetration in gran-
ite is likewise not the same for all metals as in steel, although the steel
jets reported by Brimmer (19) were probably of different material than the
steel jets utilized in this study.
B. Jet Characteristics and Jet Tip Velocity. Attempts were made to photograph
jets moving through air and helium atmospheres with a framing camera (Figure 12).
The jet was visible for the first few microseconds, then the interactions be-
tween the shock waves created by the jet tip and the atmosphere or the target
IN obscured the jet and the reaction of the target face.
NOT REPRODUCIBLE
I
Figure 12. Shaped Charge Jet 26 Microsecondsafter Initiation
Flash X-ray equipment employed by several investigators (2, 18, 25)
has shown that jets are continuous and cohesive for a short time. Subse-
quently the jet breaks up into small particles of approximately the same
length. On the basis of published date (14, 15), it is estimated that the
jets formed in this investigation remain continuous for the following approx-
imate times:
1 30
rAluminum 40-55 .secs
Copper 50-60 -psecs
Moel 50-60 lisecs
Steel 50-60 lsecs
Yellow Brass 50-60 lisecs
Pin oscilloscope techniques were employed to obtain jet tip velocities
through air and granite. 'Two shots per metal were fired to obtain the rate
of penetration and jet tip velocity. The jet tip velocity through air is
given below:
I Aluminum 2011 (T-3) 8.09 mm/sec,
Aluminum 7075 (T-6) 7.91 mm/hsec
Copper 8.87 mm/sec
Monel 9.83 mm/lsec
USteel 7.69 rmhisecYellow Brass 8.87 mm/psec
The rate of penetration into granite was obtained by placing pin setsbetween granite slabs. The velocity decreased rapidly in the first few
centimeters (Figure 13) and then decreases more slowly until maximum pene-
I. tration (minimum penetration velocity) is reached.
From the observed data there does not appear to be a direct correla-
j tion between either tip velocity or minimum penetration velocity and jet
density. The scatter of data may have been due to the inhomogeneity of the
[ rock, erratic performance of probes or subnormal performance of given charges.
C. Mechanics of Penetration. Penetration involves local shock compression
of the materials to very high pressures, possibly accompanied by some melting
I and vaporization of the target material. The process of hole enlargement in-
volves extremely high stresses and strains, as well as ejection of material
from the hole.
A shock receding into the (continuous) oncoming jet is carried below
Sthe original target surface when the jet velocity exceeds the velocity of the
shock wave generated in the jet. This critical velocity is a function of the
densities and the compressibilities of the jet and target material. As the
jet continues to penetrate, the shock wave into the target precedes the jet-
target interface. Rarefaction from the free surface of the target and the
jet modify the shock system and the shock becomes approximately conical in
shape inside the target. To reduce the probability of shorting, out of the
j 31
$1 0(A rL a) E
o tt) 0 uC'. 0) C) co ) AY
r- .2orL=C: = r- :3*S- CLE- Ia
r~0 r- a) E -
0
to 4-
0) C'.) - r~5p I- 4J0Ua) 0
Ln I-
LA-
I o I
0
CD (D
CD olcoko-n5-. ~
0 /WW) 4LD,-B
32i-
l pinsets by the shock waves rather than by the jet during rate of penetration
measurements the target slab assembly was placed inside a sand filled con-
tainer,Target Effects. The manner in whic- rock behaves under jet impact has not
yet been fully explained. Bowden (22) has suggested that five different
3' forms of deformation take place in the target material when subjected to
high velocity impact pressure by water jetsi circumferential surface frac-
I tures, subsurface flow and fracture, large scale plastic deformation lead-
ing to permanent deformation, shear deformation around the periphery of the
3 impact zone, and failure due to reflection of strass waves,
In aeneral the fractures observed in M1issouri red cranite were composites
of all these types, Attempts were made to observe the development of fractures
in the target by the jet (Figure 10). The impact of the jet formed a luminous
ionized zone (Figure 14) which obscured both the jet and the target at the
A ' point of impact, No fractures in the targets were visible up to 52 microseconds
after initiation, The fractures described below were developed due to the pres-
j sure exerted by the jet on the rock, The major 4-actures propagate in a radial
manner from the hole suggesting failure due to ter.ion. Also, fracturing con-
Ii tinued beyond the jet termination point in concrete blocks.
I
I
Figure 14. Detonation front and associated shock wave52 p sec after initiation
1 33
I The pressure at the jet impact point is estimated to be on the order of
1.5 x 106 psi, and diminishes to about one-tenth this value at minimum pene-
I tration velocity. Thus, the duration of pressure at any one point along theaxis of penetration is very short. A large portion of the energy is utilizedin pulverizing the rock, plaster flow and in transmitting kinetic energy tothe ejecta. It is estimated that less than three percent of the kinetic
1 energy of the jet is finally converted to elastic wave energy in the rock.The outgoing wave from the jet hole was strong enough in many cases to cause
1* radial fracturing (Figure 15). Concrete targets (Figure 16) also exhibited
fracturing beyond the bottom of the jet hole, although some of the fractures
may have been caused by waves reflected from the surface of the block. TheI[ rapid decrease in pressure effects outward from the axis of the hole is evi-
dent in Figure 17, which shows a zone of pulverization, grading into a zonej where the crystals are fractured, and further where the minerals show little
microfracturing.
A
41
Figure 15. Fracture pattern in granite
'1F1 34
IS
!
I
I
Figure 16. Longitudinal section of the shaped charge hole
D. Slug Formation and Metallographic Observations: As the liner begins to
collapse due to the detonation pressure (Figure 1) the inner wall of the
liner moves toward the cone axis at a greater speed than the outer wall.
This causes a flow of the liner mass leading to fast jet formation from
I the inner wall and slow jet or slug formation from the outer wall. The
process of cone collapse was photographed utilizing a mirror with a framingA camera. Figure 17 shows the interior of a cone reflected in a mirror with
the conical grid, and the development of the flow of the metal. The wall of
the liner collapses toward the cone axis forming a solid conical slug and a
jet. However, the latter is not visible.
II
j Figure 17. Cone Collapse in Advanced Stage
135
I
Slugs from yellow brass cones were smaller than those of other metals. No
slugs were recovered from Aluminum 7075. A carefully designed experiment was
designed to collect slugs from aluminum liners, and one was obtained for Alu-
minum 2011. It is suggested that zinc in the alloy is responsible for small
slugs, or for the lack of slug formation. Metallography studies were perform-
ed on the slugs and metals used for this investigation (Appendix C). The fol-
lowing conclusions were drawn from studies of the metallographs:
1) In all cases the grains have elongated and are oriented along the
direction of the slug's longitudinal axis.
2) The grains in the slug are smaller than those in the metal. In
all cases the size of the grains had reduced at least by a factor
of ten.
3) The grain size is smallest near the axis of the slug and increases
toward the edge.
4) In all of the slugs a pin hole or fracture wa3 observed along the
longitudinal axis.
- 5) For copper and possibly aluminum some evidence of melting was
present. Material from the bottom of the target hole was analyzed
microscopically. This revealed spherical inclusions indicating
possible melting of copper particles (Figure 18)
6) There was indication of recrystallization and twinning in minerals
in the granite.
7) The hardness of the slugs of aluminum 2011 and brass was less than
the undeformed metal, suggesting an annealing effect. In monel
and steel the hardness increased, suggesting a small degree of
precipitation. However, no evidence of the precipitation was
visible in the photomicrographs.
8) There was no significant change in the densities of the metal in
formation.
36
II.
I
IFigure 18. Photomicrograph of Copper imbedded in granite
x250
E. Jet Hole Characteristics: A great deal of comminuation took place in the
material immediately around the hole where the work was crushed and friable.
Spallation always occurred around the collar of the hole, probably due to re-
bound. Figure 19 shows the highly fractured granite with metal inclusions.
F
Figure 19. Photomicrograph of steel inclusion of inner~wall of a hole in the granite
x250
37
I
i4 All of the holes were coated with jet material, each having a coloration
depending upon the liner metal. In the case of brass the holes were brick
P red while for copper the holes were red. Aluminum, monel, and steel gave a
black coloration.
In all cases metal from the jet was deposited at the bottom of the holesIT in a fan shape. Four types of craters were formed (Figure 20). Type (d) had
very smooth walls and they were discolored also by carbon from the explosive.
i As indicated above, some ; f the holes contained spherical globules indicating
melting. However, except ?Jr one case (Figure 18) melting was not evidenced
T by optical microscopy. In -"me instances there was evidence of jet material
I intruding into the rock.
SUMMARY, CONCLUSIONS, AND RECOMMENDATIONS
1. Jets from the 60 degree monel, brass, and steel liners gave the deepest
penetration. Monel required greater standoff than brass and steel, but
less than aluminum.
2. Copper and brass liners gave equal penetration for 42 degree apex angles.
3. Aluminum liners were e.!asier to machine than other metals. Maraging steel
and the monel liners were the most difficult to fabricate.
4. Except for aluminum 7075 it appears that annealing has no effect on
penetration in granite.
5. Aluminum 7075'jets gave a somewhat greater penetration than aluminum 2011.
6. Liners containing zinc produced small slugs or none at all.
7. The holes in the granite were uniform and approximated right circular
cones. About 3 to 4 cm of the hole was removed by spa'ling and blast
effects for 1 in. diameter charges.
8. Fractures in granite due to the jet and blast were caused by compression,
tension, and shear failure. Rock in the direct line of the jet was highly
crushed and powdered, and the jet material had intruded into fractures in
the rock.
9. Framing camera photography was inadequate to define jet characteristics
in air although in an i,.ert atmosphere it was possible to observe the
jet for a few microseconds. Metallic probes (switches) were used to ob-
tain jet tip velocity and rate of penetration into granite slabs using a
pin oscilloscope technique.
10. Metallographic studies indicated a symmetrical liner collapse. Grains
I were highly fractured and hardness decreased in brass and aluminum, and
j 38
iISI
__' a 2 0 2 (cm) b 4 2 0 2 4 (cm)
1 20 4
CL 6
-
10 ,
112
14 -
I 16
.2 0 2 (cm) 8 4 2 2 4 (cm)
0
2
0
4 2
j 6 4[I , I
8 6
10 4J5 8I00
I12 1014 12
14
.1 Figure 20. Typical hole profiles in granite
139
a phase transition was suspected in steel liners. The density of the
slugs was the same as the undeformed metal,
11. A three-dimensional expression (Equation 3) was developed to describe
the collapse time for conical liners. For an assumed constant collapse
velocity the calculated stagnation point velocity was approximately
Kconstant.12. Penetration parameters for granite could not be calculated from equa-
tions 4-7 due to inadequate information about the jet characteristics.
Recommendations:
1. An investigation should be carried out to obtain the jet characteristics
K ~ and the minimum penetration velocities for different rocks. This infor-
.1 matlon may be used to modify equations 4 through 7.
2. The three-dimensional theory should be verified using flash x-ray equip-
ment.
3. With equations 4-7 and the three-dimensional collapse theory a computer
program may be developed to evaluate shaped charge performance of differ-
ent liners in rocks.
4. A more detailed metallurgical investigation should be undertaken to de-
termine the behavior of metal liners under high pressures,K 5. Studies should be continued to find liners which are more effective in
penetrating rock. More effective explosives, geometries and other charge
parameters are needed.
II
KI
I
1 40
'III APPENDIX A
List of Symbols
~ ICR Cone radius
: CD Cone diameter
d Wall thickness of cone
h Height of the cone
SHlim Limiting value of charge length
H.V. Hole volume
I L Length of the jet
m Mass per unit length
I me Mass of the liner element
r P Penetration
P T Total penetration
I Pmax Maximum penetration
r. Radius of the jet
I S A point between S2 and S3
S2 Normal distance to axis from inner wall of cone
S3 Normal distance to axis from outer wall of cone
S Initial collapse velocity
S3i Initial value of S3
SO Stand off
T Kinetic energy of collapse
t I Jet breakup time
tc Collapse time of liner
UD Detonation velocity of explosive
41
i Umin Minimum penetration velocity of targ3t
V Jet velocity
SVc ~ollapse velocity ot liner
V 0 Jet tip velocity
S0I Distance from virtual origin (assumed point of origin of jet)
to the target surface
a Half apex angle
K i' 8 Collapse angle
Pt/pj
Al Length of element along the slant height of cone
I Correction factor for discontinuous jet
Pt Density of target
P1 Density of jet
I
KI
I
KI,
Ku 42
IAPPENDIX B
Collapse Time and Kinetic Energy
The following assumptions were used in the development of the expres-
sions presented in the text to obtain liner collapse time and the kineticenergy of collapse:
1. Metal under high pressure and impulsive load Is considered to be
I an incompressible fluid.
2. Collapse is normal to the original slant height of the cone.
I 3. The initial collapse veloc~ty is constant over the surface of the
conc.
Consider a section of the cone and an element on the surface having'a
small length along the slant height of the cone to be AX (Figure 2). Thus,
r 2 = S2 Cos a
I r3 = S3 Cosca
and the volume of this element
V = -IA Cos (S -s ) (1)
If the volume of the element remains constant then
I V = constante
I and therefore
(2V /,CosaAk) (S2-S 2)
will be conserved as the liner is collapsing. Differentiating (S -S3)with respect to time
2S25? = 2S3S3 : 2ss
1for any value of S, thus1 s3= (s / 3) (2)
I1 43
The kinetic energy (T) of the element is given by
I T =,A~p [27rCosa SoT JS 2 OS dS (dS/dt)2
= ApTrCosa 2 S (S dS/dt)2 I(S2) dS
• S3
AZpirCosa ( 1S) dS_ 53
T AkpwCosa (S3 S3)2 In (S2/S 3) (3)
From Equation (3) S3 is given by
dS3/dt = =T3 Akp Cos S2 In S/
ThereforeFk £pwCo$ In S2/S3 ]h
dt = dS3 (4)
Integrating Equation (4) for t gives
t (rTRCSc/) 3o dt = (prAosa/T)h S3 S (In $2/$3)1 dS3
Therefore, s3 +d
tc = (pwAxCosa/T)h 1/2 3i S3In dS3fr r/Cosa \3 $ 3
Ii1 1
'3 g4
APPENDIX C
Metallography of the Metals and Slugs
The changes in microstructure following explosive impact and flow
are primarily in the distribution density of lattice defects such as dis-
locations, vacancies, interstitials, stacking faults, mechanical twins,and an amount of strain induced transformation in alloys normally suscep-
1 tible to such transitions (26). The large amount of energy imparted to
the liners by explosives causes a severe deformation and reduction in sizeof the grains. A systematic metallographic investigation was made to ob-serve the effect of high pressure generated by Composition C-4 on the liners.
A representativi sample was taken from each of the metals used to
fabricate the cones. Samples were prepared for metallographic analysis em-
ploying standar! procedures (27).
The slugs were cut and mounted in a manner to reveal the structure
along the longitudinal as well as the transverse axis. The greatest
deformation was near the center of the slug. The grains showed a flow
in the direction of the metal toward the stagnation point, In some cases
fracture at the stagnation zone was observed. Metallographs are presented
in Figures IC-16C.
Figure lC: Metallograph of aluminum 2011 (T-3). This alloy has aIface centered cubic lattice structure. it is a free machining alloy.
Grain boundaries are well defined and are equiaxed.
I Figure 2C: Metallograph of aluminum 2011 slug. The grains are
highly fractured and are about 1/150th of the original grain size. Some
i recrystallization is indicated. Fine grains are almost equiaxed. Afracture was seen along the transverse axis of the slug near the stagna-
I tion axis. The hardness of the metal had decreased from 63 RB to 21 RB.
Figure 3C: Metallograph of aluminum 7075 (T-6). This is an aluminum
zinc alloy. No slug was recivered in this case. The a grains are well
defined and are equiaxed. Mostly a grains with some black inclusions andboundary precipitation can be seen.
Figure 4C: Metallog~-ph of yellow brass. The a grains are white
and occupy about 90 percent of the area of the specimen. The grains are
well defined and are equiaxed.Figure 5C: Metallograph of the brass slug taken along the longi-
tudinal axis near the edge of the slug. The grains are fractured and
1 45
I
'I show elongation along the slug axis. The B particles had elongated
near the center of the slug and were highly fractured. The flow of
the particles was along the transverse axis of the slug. The hardness
had decreased from 73 RB to 53 RB suggesting some annealing effects.
Figures 6C, 7C and 19: Metallographs of the copper metal, slug,
and a photomicrograph of a copper particle imbedded in granite. InFigure 6C annealing twins are visible. The grains are well defined
and are equiaxed. Figure 7C shows the structure of the slug along the
longitudinal axis of the slug. No fractures were visible but a pinhole was observed at the center of the slug. The grains are well de-fined and are equiaxed. The size of the grains is about 1/10th of the
original grains. Grains are elongated along the direction of flow.
No melting was observed. The grains are completely crushed. Recrystal-
lization after deformation is apparent. Figure 19 is a photomicrograph
of the metal particles and highly fractured granite from the end of the
hole. Some melting of the metal is evidenced. The hardness of the slug
had increased from 34 RE to 14.5 RB.
Figure 8C: Metallograph of monel which shows a roughly equiaxedgrain of $ phase containing annealing twins and no second phase. Smallamounts of an unidentified second phase inclusion are seen.
j Figures 9C, iOC, and 11C: Figure 9C is a metallograph of a monel
slug taken along the longitudinal axis. The grains are highly deformed
T and have elongated along the direction of flow. Heavy deformations and
flow patterns are clearly visible. Black inclusions of a second phase
are lenticular in shape. Figure 1OC shows the structure of the slug
at the center. The stagnation point has a large crack and small frac-tures in a radial pattern. Figure lIC shows the crack at the center
i ,surrounded by very fine recrystallized grains, several orders of mag-
nitude smaller than the original grains, gradiating up to 10 percent
of the original metal grains. The hardness of the slug had increased
from 12.5 RC to 21 RC.' "|Figures 12C and 13C: Metallographs of maraging steel (Vascomax
250). The grain boundaries are well defined and the grains are equiaxed.
Annealing twins are visible. Figure 13C was taken at the edge of the
transverse axis of the slug. White lines are fractures while the black
area is unidentified.
46
Figure 14C: A sketch of the steel slug showing variations in hard-
ness. The outer edge of the metal was fractured. These fractured. These
fractures extend toward the center in a conical pattern.
Figures 15C and 16C: Metallographs of the structure at the edge of
the steel slug along the longitudinal axis and at the center of the slug.
No microstructure is visible at this magnification. Some phase transfor-
mation is suspected. The grains increase in size away from the center.
The hardness of the slug had increased from 28.5 RC to 36.75 RC (average)
suggesting some degree of precipitation. It was not possible to see pre-
Fcipitates by optical microscopy.
IIIII
i
,I 47
Fiur 3C Almiu 77Figure 4C. Yw. Bras
I • .,.,* . . * , A;
y ' "" *.q
Figure 3C. Aluminum 7075
L x250
I NOT REPRODUCIBLE
II
..# . -.. -"i
j Figure 4C. Yellow Brass
. x250
f
1*-1
Figure 11C. Monel slug along transverse axis.Recrystallization near the centercan be seen. x250
I NOT REPRODUCIBLE
TICay$)
Figure 12C. Maraging x5
1 53
I
r1
36.5 RC 38.0 RC
Figure 15D
39.0 RC1. 39.0 RC
LONGITUDINAL SECTION
INOT REPRODUCIBLE
Figure 13D Figure 16D
36.5 RC
TRANSVERSE SECTION
IFigure 140. Steel Slug and Its Hardness
1 55
5x25
NOT REPRODUCIBLE
If *1"**.*.1 e. 2''
I~~~ ~ JIM ,.*ci
4Figure 160. Maraging steel slug at center
1 56
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